Hands-on Exercise 5:

This exercise will be guiding me through the calculation of measures of spatial autocorrelation, both global and local.

Application of the measures of Spatial autocorrelation:

This exercise will be looking at the spatial pattern of a development indicator of Hunan Province in China.

Datasets used would the the same as the previous hands-on exercise.

Show the code
pacman::p_load(sf, spdep, tmap, tidyverse)

Now loading data

Show the code
hunan <- st_read(dsn = "../../data/geospatial",
                 layer = "Hunan")
Reading layer `Hunan' from data source 
  `/Users/tangtang/Desktop/IS415 Geospatial Analytics and Applications/practice/is415gaa/data/geospatial' 
  using driver `ESRI Shapefile'
Simple feature collection with 88 features and 7 fields
Geometry type: POLYGON
Dimension:     XY
Bounding box:  xmin: 108.7831 ymin: 24.6342 xmax: 114.2544 ymax: 30.12812
Geodetic CRS:  WGS 84
Show the code
hunan2012 <- read.csv("../../data/aspatial/Hunan_2012.csv")

Update main hunan table with the indicator we are interested in

Show the code
hunan <- left_join(hunan,hunan2012) %>% 
  select(1:4, 7, 15)
Joining with `by = join_by(County)`

Preparing choropleth map to show distribution with equal and quantile classification functions

Show the code
equal <- tm_shape(hunan)+
  tm_fill("GDPPC",
          n = 5,
          style = "equal") +
  tm_borders(alpha = 0.5)+
  tm_layout(main.title = "Equal interval classification")

quantile <- tm_shape(hunan)+
  tm_fill("GDPPC",
          n = 5,
          style = "quantile")+
  tm_borders(alpha = 0.5)+
  tm_layout(main.title = "Quantile interval classification")

tmap_arrange(equal,
             quantile,
             asp = 1,
             ncol = 2)

Global measures of Spatial Autocorrelation

Compute Global Spatial Autocorrelation statistics

Compute contiguity spatial weights

Show the code
wm_q <- poly2nb(hunan,
                queen = TRUE)
summary(wm_q)
Neighbour list object:
Number of regions: 88 
Number of nonzero links: 448 
Percentage nonzero weights: 5.785124 
Average number of links: 5.090909 
Link number distribution:

 1  2  3  4  5  6  7  8  9 11 
 2  2 12 16 24 14 11  4  2  1 
2 least connected regions:
30 65 with 1 link
1 most connected region:
85 with 11 links

Assign weight to each neighbour polygon (equal weight)

Show the code
rswm_q <- nb2listw(wm_q,
                   style = "W",
                   zero.policy = TRUE)
rswm_q
Characteristics of weights list object:
Neighbour list object:
Number of regions: 88 
Number of nonzero links: 448 
Percentage nonzero weights: 5.785124 
Average number of links: 5.090909 

Weights style: W 
Weights constants summary:
   n   nn S0       S1       S2
W 88 7744 88 37.86334 365.9147

Spatial Complete Randomness test for Global Spatial Autocorrelation

Maron’s I test

Show the code
moran.test(hunan$GDPPC,
           listw = rswm_q,
           zero.policy = TRUE,
           na.action = na.omit)

    Moran I test under randomisation

data:  hunan$GDPPC  
weights: rswm_q    

Moran I statistic standard deviate = 4.7351, p-value = 1.095e-06
alternative hypothesis: greater
sample estimates:
Moran I statistic       Expectation          Variance 
      0.300749970      -0.011494253       0.004348351 
What statistical conclusion can you draw from the output above?

The alternative hypothesis is adopted.

Performing permutation test for Moran’s I statistics, for 1000 simulations

Show the code
set.seed(1234)
bperm = moran.mc(hunan$GDPPC,
                 listw = rswm_q,
                 nsim = 999,
                 zero.policy = TRUE,
                 na.action = na.omit)

bperm

    Monte-Carlo simulation of Moran I

data:  hunan$GDPPC 
weights: rswm_q  
number of simulations + 1: 1000 

statistic = 0.30075, observed rank = 1000, p-value = 0.001
alternative hypothesis: greater

Visualising Moran’s I statistics

Show the code
mean(bperm$res[1:999])
[1] -0.01504572
Show the code
var(bperm$res[1:999])
[1] 0.004371574
Show the code
summary(bperm$res[1:999])
    Min.  1st Qu.   Median     Mean  3rd Qu.     Max. 
-0.18339 -0.06168 -0.02125 -0.01505  0.02611  0.27593 

Plotting Moran’s I statistics

Show the code
hist(bperm$res,
     freq = TRUE,
     breaks = 20,
     xlab = "Simulated Moran's I")
abline(v = 0,
       col = "red")

What statistical observation can you draw fro mthe output above?

The data is slightly right skewed, with a mode that is less than 0.0, which is the mean of the derived I statistics.

Challenge: Instead of using Base Graph to plot the values, plot the values by using ggplot2 package.

Geary’s C

Show the code
geary.test(hunan$GDPPC,
           listw = rswm_q)

    Geary C test under randomisation

data:  hunan$GDPPC 
weights: rswm_q 

Geary C statistic standard deviate = 3.6108, p-value = 0.0001526
alternative hypothesis: Expectation greater than statistic
sample estimates:
Geary C statistic       Expectation          Variance 
        0.6907223         1.0000000         0.0073364 
What statistical conclusion can you draw from the output above?

Performing permutation test for Geary’s C statistics

Show the code
set.seed(1234)
bperm = geary.mc(hunan$GDPPC,
               listw = rswm_q,
               nsim = 999)
bperm

    Monte-Carlo simulation of Geary C

data:  hunan$GDPPC 
weights: rswm_q 
number of simulations + 1: 1000 

statistic = 0.69072, observed rank = 1, p-value = 0.001
alternative hypothesis: greater
What statistical conclusion can you draw from the output above?

Visualising C statistics

Show the code
mean(bperm$res[1:999])
[1] 1.004402
Show the code
var(bperm$res[1:999])
[1] 0.007436493
Show the code
summary(bperm$res[1:999])
   Min. 1st Qu.  Median    Mean 3rd Qu.    Max. 
 0.7142  0.9502  1.0052  1.0044  1.0595  1.2722 

Plotting the C statistics

Show the code
hist(bperm$res, 
     freq = TRUE, 
     breaks = 20, 
     xlab = "Simulated Geary c")
abline(v = 1, 
       col = "red") 

Spatial correlogram

Moran’s I correlogram

Compute a 6-lag spatial correlogram of GDPPC

Show the code
MI_corr <- sp.correlogram(wm_q,
                          hunan$GDPPC,
                          order = 6,
                          method = "I",
                          style = "W")
plot(MI_corr)

Look at full report

Show the code
print(MI_corr)
Spatial correlogram for hunan$GDPPC 
method: Moran's I
         estimate expectation   variance standard deviate Pr(I) two sided    
1 (88)  0.3007500  -0.0114943  0.0043484           4.7351       2.189e-06 ***
2 (88)  0.2060084  -0.0114943  0.0020962           4.7505       2.029e-06 ***
3 (88)  0.0668273  -0.0114943  0.0014602           2.0496        0.040400 *  
4 (88)  0.0299470  -0.0114943  0.0011717           1.2107        0.226015    
5 (88) -0.1530471  -0.0114943  0.0012440          -4.0134       5.984e-05 ***
6 (88) -0.1187070  -0.0114943  0.0016791          -2.6164        0.008886 ** 
---
Signif. codes:  0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
What statistical observation can you draw from the plot above?

Geary’s C correlogram

Compute a 6-lag spatial correlogram of GDPPC

Show the code
GC_corr <- sp.correlogram(wm_q,
                          hunan$GDPPC,
                          order = 6,
                          method = "C",
                          style = "W")
plot(GC_corr)

Look at full report

Show the code
print(GC_corr)
Spatial correlogram for hunan$GDPPC 
method: Geary's C
        estimate expectation  variance standard deviate Pr(I) two sided    
1 (88) 0.6907223   1.0000000 0.0073364          -3.6108       0.0003052 ***
2 (88) 0.7630197   1.0000000 0.0049126          -3.3811       0.0007220 ***
3 (88) 0.9397299   1.0000000 0.0049005          -0.8610       0.3892612    
4 (88) 1.0098462   1.0000000 0.0039631           0.1564       0.8757128    
5 (88) 1.2008204   1.0000000 0.0035568           3.3673       0.0007592 ***
6 (88) 1.0773386   1.0000000 0.0058042           1.0151       0.3100407    
---
Signif. codes:  0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1

Local measures of Spatial Autocorrelation

In this part of the exercise, I am expected to compute the global measures of spatial autocorrelation first, before I can start computing the local measures.

The local measures, also known as the Local Indicators of Spatial Association aka LISA, is used to detect cluster(s) or outlier in the given data.

Local Moran’s I statistics

Show the code
fips <- order(hunan$County)
localMI <- localmoran(hunan$GDPPC, rswm_q)
head(localMI)
            Ii          E.Ii       Var.Ii        Z.Ii Pr(z != E(Ii))
1 -0.001468468 -2.815006e-05 4.723841e-04 -0.06626904      0.9471636
2  0.025878173 -6.061953e-04 1.016664e-02  0.26266425      0.7928094
3 -0.011987646 -5.366648e-03 1.133362e-01 -0.01966705      0.9843090
4  0.001022468 -2.404783e-07 5.105969e-06  0.45259801      0.6508382
5  0.014814881 -6.829362e-05 1.449949e-03  0.39085814      0.6959021
6 -0.038793829 -3.860263e-04 6.475559e-03 -0.47728835      0.6331568

localmoran() returns a matrix of values - Ii: local Moran’s I statistics

  • E.Ii: the expectation of local moran statistic under the randomisation hypothesis

  • Var.Ii: the variance of local moran statistic under the randomisation hypothesis

  • Z.Ii: the standard deviate of local moran statistic

  • Pr(z != E(Ii)): p-value of local moran statistic

Look at content of the local Moran matrix

Show the code
printCoefmat(data.frame(
  localMI[fips,], 
  row.names = hunan$County[fips]),
  check.names = FALSE)
                       Ii        E.Ii      Var.Ii        Z.Ii Pr.z....E.Ii..
Anhua         -2.2493e-02 -5.0048e-03  5.8235e-02 -7.2467e-02         0.9422
Anren         -3.9932e-01 -7.0111e-03  7.0348e-02 -1.4791e+00         0.1391
Anxiang       -1.4685e-03 -2.8150e-05  4.7238e-04 -6.6269e-02         0.9472
Baojing        3.4737e-01 -5.0089e-03  8.3636e-02  1.2185e+00         0.2230
Chaling        2.0559e-02 -9.6812e-04  2.7711e-02  1.2932e-01         0.8971
Changning     -2.9868e-05 -9.0010e-09  1.5105e-07 -7.6828e-02         0.9388
Changsha       4.9022e+00 -2.1348e-01  2.3194e+00  3.3590e+00         0.0008
Chengbu        7.3725e-01 -1.0534e-02  2.2132e-01  1.5895e+00         0.1119
Chenxi         1.4544e-01 -2.8156e-03  4.7116e-02  6.8299e-01         0.4946
Cili           7.3176e-02 -1.6747e-03  4.7902e-02  3.4200e-01         0.7324
Dao            2.1420e-01 -2.0824e-03  4.4123e-02  1.0297e+00         0.3032
Dongan         1.5210e-01 -6.3485e-04  1.3471e-02  1.3159e+00         0.1882
Dongkou        5.2918e-01 -6.4461e-03  1.0748e-01  1.6338e+00         0.1023
Fenghuang      1.8013e-01 -6.2832e-03  1.3257e-01  5.1198e-01         0.6087
Guidong       -5.9160e-01 -1.3086e-02  3.7003e-01 -9.5104e-01         0.3416
Guiyang        1.8240e-01 -3.6908e-03  3.2610e-02  1.0305e+00         0.3028
Guzhang        2.8466e-01 -8.5054e-03  1.4152e-01  7.7931e-01         0.4358
Hanshou        2.5878e-02 -6.0620e-04  1.0167e-02  2.6266e-01         0.7928
Hengdong       9.9964e-03 -4.9063e-04  6.7742e-03  1.2742e-01         0.8986
Hengnan        2.8064e-02 -3.2160e-04  3.7597e-03  4.6294e-01         0.6434
Hengshan      -5.8201e-03 -3.0437e-05  5.1076e-04 -2.5618e-01         0.7978
Hengyang       6.2997e-02 -1.3046e-03  2.1865e-02  4.3486e-01         0.6637
Hongjiang      1.8790e-01 -2.3019e-03  3.1725e-02  1.0678e+00         0.2856
Huarong       -1.5389e-02 -1.8667e-03  8.1030e-02 -4.7503e-02         0.9621
Huayuan        8.3772e-02 -8.5569e-04  2.4495e-02  5.4072e-01         0.5887
Huitong        2.5997e-01 -5.2447e-03  1.1077e-01  7.9685e-01         0.4255
Jiahe         -1.2431e-01 -3.0550e-03  5.1111e-02 -5.3633e-01         0.5917
Jianghua       2.8651e-01 -3.8280e-03  8.0968e-02  1.0204e+00         0.3076
Jiangyong      2.4337e-01 -2.7082e-03  1.1746e-01  7.1800e-01         0.4728
Jingzhou       1.8270e-01 -8.5106e-04  2.4363e-02  1.1759e+00         0.2396
Jinshi        -1.1988e-02 -5.3666e-03  1.1334e-01 -1.9667e-02         0.9843
Jishou        -2.8680e-01 -2.6305e-03  4.4028e-02 -1.3543e+00         0.1756
Lanshan        6.3334e-02 -9.6365e-04  2.0441e-02  4.4972e-01         0.6529
Leiyang        1.1581e-02 -1.4948e-04  2.5082e-03  2.3422e-01         0.8148
Lengshuijiang -1.7903e+00 -8.2129e-02  2.1598e+00 -1.1623e+00         0.2451
Li             1.0225e-03 -2.4048e-07  5.1060e-06  4.5260e-01         0.6508
Lianyuan      -1.4672e-01 -1.8983e-03  1.9145e-02 -1.0467e+00         0.2952
Liling         1.3774e+00 -1.5097e-02  4.2601e-01  2.1335e+00         0.0329
Linli          1.4815e-02 -6.8294e-05  1.4499e-03  3.9086e-01         0.6959
Linwu         -2.4621e-03 -9.0703e-06  1.9258e-04 -1.7676e-01         0.8597
Linxiang       6.5904e-02 -2.9028e-03  2.5470e-01  1.3634e-01         0.8916
Liuyang        3.3688e+00 -7.7502e-02  1.5180e+00  2.7972e+00         0.0052
Longhui        8.0801e-01 -1.1377e-02  1.5538e-01  2.0787e+00         0.0376
Longshan       7.5663e-01 -1.1100e-02  3.1449e-01  1.3690e+00         0.1710
Luxi           1.8177e-01 -2.4855e-03  3.4249e-02  9.9561e-01         0.3194
Mayang         2.1852e-01 -5.8773e-03  9.8049e-02  7.1663e-01         0.4736
Miluo          1.8704e+00 -1.6927e-02  2.7925e-01  3.5715e+00         0.0004
Nan           -9.5789e-03 -4.9497e-04  6.8341e-03 -1.0988e-01         0.9125
Ningxiang      1.5607e+00 -7.3878e-02  8.0012e-01  1.8274e+00         0.0676
Ningyuan       2.0910e-01 -7.0884e-03  8.2306e-02  7.5356e-01         0.4511
Pingjiang     -9.8964e-01 -2.6457e-03  5.6027e-02 -4.1698e+00         0.0000
Qidong         1.1806e-01 -2.1207e-03  2.4747e-02  7.6396e-01         0.4449
Qiyang         6.1966e-02 -7.3374e-04  8.5743e-03  6.7712e-01         0.4983
Rucheng       -3.6992e-01 -8.8999e-03  2.5272e-01 -7.1814e-01         0.4727
Sangzhi        2.5053e-01 -4.9470e-03  6.8000e-02  9.7972e-01         0.3272
Shaodong      -3.2659e-02 -3.6592e-05  5.0546e-04 -1.4510e+00         0.1468
Shaoshan       2.1223e+00 -5.0227e-02  1.3668e+00  1.8583e+00         0.0631
Shaoyang       5.9499e-01 -1.1253e-02  1.3012e-01  1.6807e+00         0.0928
Shimen        -3.8794e-02 -3.8603e-04  6.4756e-03 -4.7729e-01         0.6332
Shuangfeng     9.2835e-03 -2.2867e-03  3.1516e-02  6.5174e-02         0.9480
Shuangpai      8.0591e-02 -3.1366e-04  8.9838e-03  8.5358e-01         0.3933
Suining        3.7585e-01 -3.5933e-03  4.1870e-02  1.8544e+00         0.0637
Taojiang      -2.5394e-01 -1.2395e-03  1.4477e-02 -2.1002e+00         0.0357
Taoyuan        1.4729e-02 -1.2039e-04  8.5103e-04  5.0903e-01         0.6107
Tongdao        4.6482e-01 -6.9870e-03  1.9879e-01  1.0582e+00         0.2900
Wangcheng      4.4220e+00 -1.1067e-01  1.3596e+00  3.8873e+00         0.0001
Wugang         7.1003e-01 -7.8144e-03  1.0710e-01  2.1935e+00         0.0283
Xiangtan       2.4530e-01 -3.6457e-04  3.2319e-03  4.3213e+00         0.0000
Xiangxiang     2.6271e-01 -1.2703e-03  2.1290e-02  1.8092e+00         0.0704
Xiangyin       5.4525e-01 -4.7442e-03  7.9236e-02  1.9539e+00         0.0507
Xinhua         1.1810e-01 -6.2649e-03  8.6001e-02  4.2409e-01         0.6715
Xinhuang       1.5725e-01 -4.1820e-03  3.6648e-01  2.6667e-01         0.7897
Xinning        6.8928e-01 -9.6674e-03  2.0328e-01  1.5502e+00         0.1211
Xinshao        5.7578e-02 -8.5932e-03  1.1769e-01  1.9289e-01         0.8470
Xintian       -7.4050e-03 -5.1493e-03  1.0877e-01 -6.8395e-03         0.9945
Xupu           3.2406e-01 -5.7468e-03  5.7735e-02  1.3726e+00         0.1699
Yanling       -6.9021e-02 -5.9211e-04  9.9306e-03 -6.8667e-01         0.4923
Yizhang       -2.6844e-01 -2.2463e-03  4.7588e-02 -1.2202e+00         0.2224
Yongshun       6.3064e-01 -1.1350e-02  1.8830e-01  1.4795e+00         0.1390
Yongxing       4.3411e-01 -9.0735e-03  1.5088e-01  1.1409e+00         0.2539
You            7.8750e-02 -7.2728e-03  1.2116e-01  2.4714e-01         0.8048
Yuanjiang      2.0004e-04 -1.7760e-04  2.9798e-03  6.9181e-03         0.9945
Yuanling       8.7298e-03 -2.2981e-06  2.3221e-05  1.8121e+00         0.0700
Yueyang        4.1189e-02 -1.9768e-04  2.3113e-03  8.6085e-01         0.3893
Zhijiang       1.0476e-01 -7.8123e-04  1.3100e-02  9.2214e-01         0.3565
Zhongfang     -2.2685e-01 -2.1455e-03  3.5927e-02 -1.1855e+00         0.2358
Zhuzhou        3.2864e-01 -5.2432e-04  7.2391e-03  3.8688e+00         0.0001
Zixing        -7.6849e-01 -8.8210e-02  9.4057e-01 -7.0144e-01         0.4830

Mapping Local Moran values

Append local moran into hunan sp dataframe

Show the code
hunan.localMI <- cbind(hunan,localMI) %>%
  rename(Pr.Ii = Pr.z....E.Ii..)

Plot local Moran values

Show the code
tm_shape(hunan.localMI) +
  tm_fill(col = "Ii", 
          style = "pretty",
          palette = "RdBu",
          title = "local moran statistics") +
  tm_borders(alpha = 0.5)
Variable(s) "Ii" contains positive and negative values, so midpoint is set to 0. Set midpoint = NA to show the full spectrum of the color palette.

Plot local Moran p-values

Show the code
tm_shape(hunan.localMI) +
  tm_fill(col = "Pr.Ii", 
          breaks = c(-Inf, 0.001, 0.01, 0.05, 0.1, Inf),
          palette = "-Blues", 
          title = "local Moran's I p-values") +
  tm_borders(alpha = 0.5)

Map both together

Show the code
localMI.map <- tm_shape(hunan.localMI) +
  tm_fill(col = "Ii", 
          style = "pretty", 
          title = "local moran statistics") +
  tm_borders(alpha = 0.5)

pvalue.map <- tm_shape(hunan.localMI) +
  tm_fill(col = "Pr.Ii", 
          breaks=c(-Inf, 0.001, 0.01, 0.05, 0.1, Inf),
          palette="-Blues", 
          title = "local Moran's I p-values") +
  tm_borders(alpha = 0.5)

tmap_arrange(localMI.map, pvalue.map, asp=1, ncol=2)
Variable(s) "Ii" contains positive and negative values, so midpoint is set to 0. Set midpoint = NA to show the full spectrum of the color palette.

LISA Cluster map

Get Moran scatter plot

Show the code
nci <- moran.plot(hunan$GDPPC, rswm_q,
                  labels=as.character(hunan$County), 
                  xlab="GDPPC 2012", 
                  ylab="Spatially Lag GDPPC 2012")

Plot is split into 4 quardrants

  1. Top right: Areas with HIGH GDPPC and surrounded by areas with average GDPPC

  2. Bottom right: Areas with HIGH GDPPC and surrounded by areas with low and high GDPPC

  3. Top left: Areas with LOW GDPPC and surrounded by areas with low and high GDPPC

  4. Bottom left: Areas with LOW GDPPC and surrounded by areas with average GDPPC

Plot Moran scatterplot with standardised variable

Show the code
# scale column first
hunan$Z.GDPPC <- scale(hunan$GDPPC) %>% 
  as.vector 

nci2 <- moran.plot(hunan$Z.GDPPC, rswm_q,
                   labels=as.character(hunan$County),
                   xlab="z-GDPPC 2012", 
                   ylab="Spatially Lag z-GDPPC 2012")

Prepare LISA map classes

Show the code
quadrant <- vector(mode="numeric",length=nrow(localMI))

# derive spatially lagged variable an centre the variable around its mean
hunan$lag_GDPPC <- lag.listw(rswm_q, hunan$GDPPC)
DV <- hunan$lag_GDPPC - mean(hunan$lag_GDPPC)     

LM_I <- localMI[,1] - mean(localMI[,1])    

# set significance level
signif <- 0.05

# command lines define the low-low (1), low-high (2), high-low (3) and high-high (4) categories
quadrant[DV <0 & LM_I>0] <- 1
quadrant[DV >0 & LM_I<0] <- 2
quadrant[DV <0 & LM_I<0] <- 3  
quadrant[DV >0 & LM_I>0] <- 4      

# non-significant Moran in the category 0
quadrant[localMI[,5]>signif] <- 0

Plot the LISA map

Show the code
hunan.localMI$quadrant <- quadrant
colors <- c("#ffffff", "#2c7bb6", "#abd9e9", "#fdae61", "#d7191c")
clusters <- c("insignificant", "low-low", "low-high", "high-low", "high-high")

tm_shape(hunan.localMI) +
  tm_fill(col = "quadrant", 
          style = "cat", 
          palette = colors[c(sort(unique(quadrant)))+1], 
          labels = clusters[c(sort(unique(quadrant)))+1],
          popup.vars = c("")) +
  tm_view(set.zoom.limits = c(11,17)) +
  tm_borders(alpha=0.5)

Plot local Moran I value and corresponding p-value map

Show the code
gdppc <- qtm(hunan, "GDPPC")

hunan.localMI$quadrant <- quadrant
colors <- c("#ffffff", "#2c7bb6", "#abd9e9", "#fdae61", "#d7191c")
clusters <- c("insignificant", "low-low", "low-high", "high-low", "high-high")

LISAmap <- tm_shape(hunan.localMI) +
  tm_fill(col = "quadrant", 
          style = "cat", 
          palette = colors[c(sort(unique(quadrant)))+1], 
          labels = clusters[c(sort(unique(quadrant)))+1],
          popup.vars = c("")) +
  tm_view(set.zoom.limits = c(11,17)) +
  tm_borders(alpha=0.5)

tmap_arrange(gdppc, LISAmap, 
             asp=1, ncol=2)

Hot spot and Cold spot Analysis

Other than clusters and outlier, localised spatial statistics can also used to detect hot and/or cold spots.

The specific technique is Gentis and Ord’s G statistics.

  • Detect spatial anomalies

  • looks at neighbours within a defined proximity to identify where either high or low values clutser spatially

  • statistically significant hot-spots are recognised as areas of high values where other areas within a neighbourhood range also share high values too

Step 1: Derive spatial weight matrix

Get lat, long values for centriods

Show the code
longitude <- map_dbl(hunan$geometry, ~st_centroid(.x)[[1]])
latitude <- map_dbl(hunan$geometry, ~st_centroid(.x)[[2]])
coords <- cbind(longitude, latitude)

Determine cut-off distance

Show the code
k1 <- knn2nb(knearneigh(coords))
k1dists <- unlist(nbdists(k1, coords, longlat = TRUE))
summary(k1dists)
   Min. 1st Qu.  Median    Mean 3rd Qu.    Max. 
  24.79   32.57   38.01   39.07   44.52   61.79 

Compute fixed distance weight matrix

Show the code
wm_d62 <- dnearneigh(coords, 0, 62, longlat = TRUE)
wm_d62
Neighbour list object:
Number of regions: 88 
Number of nonzero links: 324 
Percentage nonzero weights: 4.183884 
Average number of links: 3.681818 
Show the code
# convert nb object into spatial weight object
wm62_lw <- nb2listw(wm_d62, style = 'B')
summary(wm62_lw)
Characteristics of weights list object:
Neighbour list object:
Number of regions: 88 
Number of nonzero links: 324 
Percentage nonzero weights: 4.183884 
Average number of links: 3.681818 
Link number distribution:

 1  2  3  4  5  6 
 6 15 14 26 20  7 
6 least connected regions:
6 15 30 32 56 65 with 1 link
7 most connected regions:
21 28 35 45 50 52 82 with 6 links

Weights style: B 
Weights constants summary:
   n   nn  S0  S1   S2
B 88 7744 324 648 5440

Compute adaptive distance weight matrix

Show the code
knn <- knn2nb(knearneigh(coords, k=8))
knn
Neighbour list object:
Number of regions: 88 
Number of nonzero links: 704 
Percentage nonzero weights: 9.090909 
Average number of links: 8 
Non-symmetric neighbours list
Show the code
# convert nb object into spatial weight object
knn_lw <- nb2listw(knn, style = 'B')
summary(knn_lw)
Characteristics of weights list object:
Neighbour list object:
Number of regions: 88 
Number of nonzero links: 704 
Percentage nonzero weights: 9.090909 
Average number of links: 8 
Non-symmetric neighbours list
Link number distribution:

 8 
88 
88 least connected regions:
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 with 8 links
88 most connected regions:
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 with 8 links

Weights style: B 
Weights constants summary:
   n   nn  S0   S1    S2
B 88 7744 704 1300 23014

Step 2: Computing Gi statistics

Gi statistics with fixed distance

Show the code
fips <- order(hunan$County)
gi.fixed <- localG(hunan$GDPPC, wm62_lw)
gi.fixed
 [1]  0.436075843 -0.265505650 -0.073033665  0.413017033  0.273070579
 [6] -0.377510776  2.863898821  2.794350420  5.216125401  0.228236603
[11]  0.951035346 -0.536334231  0.176761556  1.195564020 -0.033020610
[16]  1.378081093 -0.585756761 -0.419680565  0.258805141  0.012056111
[21] -0.145716531 -0.027158687 -0.318615290 -0.748946051 -0.961700582
[26] -0.796851342 -1.033949773 -0.460979158 -0.885240161 -0.266671512
[31] -0.886168613 -0.855476971 -0.922143185 -1.162328599  0.735582222
[36] -0.003358489 -0.967459309 -1.259299080 -1.452256513 -1.540671121
[41] -1.395011407 -1.681505286 -1.314110709 -0.767944457 -0.192889342
[46]  2.720804542  1.809191360 -1.218469473 -0.511984469 -0.834546363
[51] -0.908179070 -1.541081516 -1.192199867 -1.075080164 -1.631075961
[56] -0.743472246  0.418842387  0.832943753 -0.710289083 -0.449718820
[61] -0.493238743 -1.083386776  0.042979051  0.008596093  0.136337469
[66]  2.203411744  2.690329952  4.453703219 -0.340842743 -0.129318589
[71]  0.737806634 -1.246912658  0.666667559  1.088613505 -0.985792573
[76]  1.233609606 -0.487196415  1.626174042 -1.060416797  0.425361422
[81] -0.837897118 -0.314565243  0.371456331  4.424392623 -0.109566928
[86]  1.364597995 -1.029658605 -0.718000620
attr(,"internals")
               Gi      E(Gi)        V(Gi)        Z(Gi) Pr(z != E(Gi))
 [1,] 0.064192949 0.05747126 2.375922e-04  0.436075843   6.627817e-01
 [2,] 0.042300020 0.04597701 1.917951e-04 -0.265505650   7.906200e-01
 [3,] 0.044961480 0.04597701 1.933486e-04 -0.073033665   9.417793e-01
 [4,] 0.039475779 0.03448276 1.461473e-04  0.413017033   6.795941e-01
 [5,] 0.049767939 0.04597701 1.927263e-04  0.273070579   7.847990e-01
 [6,] 0.008825335 0.01149425 4.998177e-05 -0.377510776   7.057941e-01
 [7,] 0.050807266 0.02298851 9.435398e-05  2.863898821   4.184617e-03
 [8,] 0.083966739 0.04597701 1.848292e-04  2.794350420   5.200409e-03
 [9,] 0.115751554 0.04597701 1.789361e-04  5.216125401   1.827045e-07
[10,] 0.049115587 0.04597701 1.891013e-04  0.228236603   8.194623e-01
[11,] 0.045819180 0.03448276 1.420884e-04  0.951035346   3.415864e-01
[12,] 0.049183846 0.05747126 2.387633e-04 -0.536334231   5.917276e-01
[13,] 0.048429181 0.04597701 1.924532e-04  0.176761556   8.596957e-01
[14,] 0.034733752 0.02298851 9.651140e-05  1.195564020   2.318667e-01
[15,] 0.011262043 0.01149425 4.945294e-05 -0.033020610   9.736582e-01
[16,] 0.065131196 0.04597701 1.931870e-04  1.378081093   1.681783e-01
[17,] 0.027587075 0.03448276 1.385862e-04 -0.585756761   5.580390e-01
[18,] 0.029409313 0.03448276 1.461397e-04 -0.419680565   6.747188e-01
[19,] 0.061466754 0.05747126 2.383385e-04  0.258805141   7.957856e-01
[20,] 0.057656917 0.05747126 2.371303e-04  0.012056111   9.903808e-01
[21,] 0.066518379 0.06896552 2.820326e-04 -0.145716531   8.841452e-01
[22,] 0.045599896 0.04597701 1.928108e-04 -0.027158687   9.783332e-01
[23,] 0.030646753 0.03448276 1.449523e-04 -0.318615290   7.500183e-01
[24,] 0.035635552 0.04597701 1.906613e-04 -0.748946051   4.538897e-01
[25,] 0.032606647 0.04597701 1.932888e-04 -0.961700582   3.362000e-01
[26,] 0.035001352 0.04597701 1.897172e-04 -0.796851342   4.255374e-01
[27,] 0.012746354 0.02298851 9.812587e-05 -1.033949773   3.011596e-01
[28,] 0.061287917 0.06896552 2.773884e-04 -0.460979158   6.448136e-01
[29,] 0.014277403 0.02298851 9.683314e-05 -0.885240161   3.760271e-01
[30,] 0.009622875 0.01149425 4.924586e-05 -0.266671512   7.897221e-01
[31,] 0.014258398 0.02298851 9.705244e-05 -0.886168613   3.755267e-01
[32,] 0.005453443 0.01149425 4.986245e-05 -0.855476971   3.922871e-01
[33,] 0.043283712 0.05747126 2.367109e-04 -0.922143185   3.564539e-01
[34,] 0.020763514 0.03448276 1.393165e-04 -1.162328599   2.451020e-01
[35,] 0.081261843 0.06896552 2.794398e-04  0.735582222   4.619850e-01
[36,] 0.057419907 0.05747126 2.338437e-04 -0.003358489   9.973203e-01
[37,] 0.013497133 0.02298851 9.624821e-05 -0.967459309   3.333145e-01
[38,] 0.019289310 0.03448276 1.455643e-04 -1.259299080   2.079223e-01
[39,] 0.025996272 0.04597701 1.892938e-04 -1.452256513   1.464303e-01
[40,] 0.016092694 0.03448276 1.424776e-04 -1.540671121   1.233968e-01
[41,] 0.035952614 0.05747126 2.379439e-04 -1.395011407   1.630124e-01
[42,] 0.031690963 0.05747126 2.350604e-04 -1.681505286   9.266481e-02
[43,] 0.018750079 0.03448276 1.433314e-04 -1.314110709   1.888090e-01
[44,] 0.015449080 0.02298851 9.638666e-05 -0.767944457   4.425202e-01
[45,] 0.065760689 0.06896552 2.760533e-04 -0.192889342   8.470456e-01
[46,] 0.098966900 0.05747126 2.326002e-04  2.720804542   6.512325e-03
[47,] 0.085415780 0.05747126 2.385746e-04  1.809191360   7.042128e-02
[48,] 0.038816536 0.05747126 2.343951e-04 -1.218469473   2.230456e-01
[49,] 0.038931873 0.04597701 1.893501e-04 -0.511984469   6.086619e-01
[50,] 0.055098610 0.06896552 2.760948e-04 -0.834546363   4.039732e-01
[51,] 0.033405005 0.04597701 1.916312e-04 -0.908179070   3.637836e-01
[52,] 0.043040784 0.06896552 2.829941e-04 -1.541081516   1.232969e-01
[53,] 0.011297699 0.02298851 9.615920e-05 -1.192199867   2.331829e-01
[54,] 0.040968457 0.05747126 2.356318e-04 -1.075080164   2.823388e-01
[55,] 0.023629663 0.04597701 1.877170e-04 -1.631075961   1.028743e-01
[56,] 0.006281129 0.01149425 4.916619e-05 -0.743472246   4.571958e-01
[57,] 0.063918654 0.05747126 2.369553e-04  0.418842387   6.753313e-01
[58,] 0.070325003 0.05747126 2.381374e-04  0.832943753   4.048765e-01
[59,] 0.025947288 0.03448276 1.444058e-04 -0.710289083   4.775249e-01
[60,] 0.039752578 0.04597701 1.915656e-04 -0.449718820   6.529132e-01
[61,] 0.049934283 0.05747126 2.334965e-04 -0.493238743   6.218439e-01
[62,] 0.030964195 0.04597701 1.920248e-04 -1.083386776   2.786368e-01
[63,] 0.058129184 0.05747126 2.343319e-04  0.042979051   9.657182e-01
[64,] 0.046096514 0.04597701 1.932637e-04  0.008596093   9.931414e-01
[65,] 0.012459080 0.01149425 5.008051e-05  0.136337469   8.915545e-01
[66,] 0.091447733 0.05747126 2.377744e-04  2.203411744   2.756574e-02
[67,] 0.049575872 0.02298851 9.766513e-05  2.690329952   7.138140e-03
[68,] 0.107907212 0.04597701 1.933581e-04  4.453703219   8.440175e-06
[69,] 0.019616151 0.02298851 9.789454e-05 -0.340842743   7.332220e-01
[70,] 0.032923393 0.03448276 1.454032e-04 -0.129318589   8.971056e-01
[71,] 0.030317663 0.02298851 9.867859e-05  0.737806634   4.606320e-01
[72,] 0.019437582 0.03448276 1.455870e-04 -1.246912658   2.124295e-01
[73,] 0.055245460 0.04597701 1.932838e-04  0.666667559   5.049845e-01
[74,] 0.074278054 0.05747126 2.383538e-04  1.088613505   2.763244e-01
[75,] 0.013269580 0.02298851 9.719982e-05 -0.985792573   3.242349e-01
[76,] 0.049407829 0.03448276 1.463785e-04  1.233609606   2.173484e-01
[77,] 0.028605749 0.03448276 1.455139e-04 -0.487196415   6.261191e-01
[78,] 0.039087662 0.02298851 9.801040e-05  1.626174042   1.039126e-01
[79,] 0.031447120 0.04597701 1.877464e-04 -1.060416797   2.889550e-01
[80,] 0.064005294 0.05747126 2.359641e-04  0.425361422   6.705732e-01
[81,] 0.044606529 0.05747126 2.357330e-04 -0.837897118   4.020885e-01
[82,] 0.063700493 0.06896552 2.801427e-04 -0.314565243   7.530918e-01
[83,] 0.051142205 0.04597701 1.933560e-04  0.371456331   7.102977e-01
[84,] 0.102121112 0.04597701 1.610278e-04  4.424392623   9.671399e-06
[85,] 0.021901462 0.02298851 9.843172e-05 -0.109566928   9.127528e-01
[86,] 0.064931813 0.04597701 1.929430e-04  1.364597995   1.723794e-01
[87,] 0.031747344 0.04597701 1.909867e-04 -1.029658605   3.031703e-01
[88,] 0.015893319 0.02298851 9.765131e-05 -0.718000620   4.727569e-01
attr(,"cluster")
 [1] Low  Low  High High High High High High High Low  Low  High Low  Low  Low 
[16] High High High High Low  High High Low  Low  High Low  Low  Low  Low  Low 
[31] Low  Low  Low  High Low  Low  Low  Low  Low  Low  High Low  Low  Low  Low 
[46] High High Low  Low  Low  Low  High Low  Low  Low  Low  Low  High Low  Low 
[61] Low  Low  Low  High High High Low  High Low  Low  High Low  High High Low 
[76] High Low  Low  Low  Low  Low  Low  High High Low  High Low  Low 
Levels: Low High
attr(,"gstari")
[1] FALSE
attr(,"call")
localG(x = hunan$GDPPC, listw = wm62_lw)
attr(,"class")
[1] "localG"
Show the code
# join gi stat to main hunan frame
hunan.gi <- cbind(hunan, as.matrix(gi.fixed)) %>%
  rename(gstat_fixed = as.matrix.gi.fixed.)

Gi statistics with adaptive distance

Show the code
fips <- order(hunan$County)
gi.adaptive <- localG(hunan$GDPPC, knn_lw)
hunan.gi <- cbind(hunan.gi, as.matrix(gi.adaptive)) %>%
  rename(gstat_adaptive = as.matrix.gi.adaptive.)

Step 3: Mapping Gi Statistics

Map Gi statistics with fixed distance

Show the code
gdppc <- qtm(hunan, "GDPPC")

Gimap <-tm_shape(hunan.gi) +
  tm_fill(col = "gstat_fixed", 
          style = "pretty",
          palette="-RdBu",
          title = "local Gi") +
  tm_borders(alpha = 0.5)

tmap_arrange(gdppc, 
             Gimap, 
             asp = 1, 
             ncol = 2)
Variable(s) "gstat_fixed" contains positive and negative values, so midpoint is set to 0. Set midpoint = NA to show the full spectrum of the color palette.

Map Gi statistics with adaptive distance

Show the code
gdppc<- qtm(hunan, "GDPPC")

Gimap <- tm_shape(hunan.gi) + 
  tm_fill(col = "gstat_adaptive", 
          style = "pretty", 
          palette="-RdBu", 
          title = "local Gi") + 
  tm_borders(alpha = 0.5)

tmap_arrange(gdppc, 
             Gimap, 
             asp=1, 
             ncol=2)
Variable(s) "gstat_adaptive" contains positive and negative values, so midpoint is set to 0. Set midpoint = NA to show the full spectrum of the color palette.